Kinematic modifications of the lower limb during the acceleration phase of bend sprinting

Judson, Laura J; Churchill, Sarah; Barnes, Andrew; Stone, Joseph; Brookes, Ian G A; Wheat, Jonathan

doi:10.1080/02640414.2019.1699006

Cited by 8 publications

(46 citation statements)

References 24 publications

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“…After the starting blocks exit, the left mean stance times in the curve were longer than in the straight (see Figure 5). Consequently, our findings are consistent with what was previously reported at 13 m 28 and 40 m 9,13 . On the other hand, no changes were reported for the right limb (see Figure 5), which is also similar to Churchill et al's 9,13 .…”

Section: Discussionsupporting

confidence: 93%

Are the ground reaction forces altered by the curve and with the increasing sprinting velocity?

Millot,

Pradon,

Cecchelli

et al. 2024

Scandinavian Med Sci Sports

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In 200‐ and 400‐m races, 58% of the total distance to cover is in the curve. In the curve, the sprinting performance is decreased in comparison to the straight. However, the reasons for this decreased performance is not well understood. Thus, the aim of this study was to identify the kinetic parameters underpinning the sprinting performance in the curve in comparison to the straight. Nineteen experienced‐to‐elite curve specialists performed five sprints in the straight and in the curve (radius 41.58 m): 10, 15, 20, 30, and 40 m. The left and the right vertical, anterior–posterior, medial‐lateral, and resultant ground reaction forces (respectively , , , and ), the associated impulses (respectively , , , and ) and the stance times of each side were averaged over each distance. In the curve, the time to cover the 40‐m sprint was longer than in the straight (5.52 ± 0.25 vs. 5.47 ± 0.23 s, respectively). Additionally, the left and the right and were lower than in the straight while the left and the right increased, meaning that the was more medial. The left was also lower than in the straight while the left stance times increased to keep the left similar to the straight to maintain the subsequent swing time. Overall, the sprinting performance was reduced in the curve due to a reduction in the left and the right and , that were likely attributed to the concomitant increased to adopt a curvilinear motion.

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Section: Discussionsupporting

confidence: 93%

Are the ground reaction forces altered by the curve and with the increasing sprinting velocity?

Millot,

Pradon,

Cecchelli

et al. 2024

Scandinavian Med Sci Sports

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show abstract

“…The production of cGRF and vGRF may differ between the inside and outside legs as a result of differences in the peak ankle plantarflexor moment ( Judson et al, 2020a ) and peak ankle eversion angle ( Alt et al, 2015 ) during maximum effort curve sprinting, but further research is needed to investigate the effect of curve radii on leg-specific joint kinetics, joint kinematics and GRF production. Athletes seeking to improve curve sprinting performance may benefit from strengthening ankle plantarflexor muscles under a range of frontal plane ankle orientations, as maximum ankle inversion and eversion angles significantly differ during curve versus straight sprinting ( Alt et al, 2015 ; Judson et al, 2020b ).…”

Section: Discussionmentioning

confidence: 99%

Maximum velocity and leg-specific ground reaction force production change with radius during flat curve sprinting

Diaz,

Alcantara,

Grabowski

2024

Journal of Experimental Biology

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Humans attain slower maximum velocity (vmax) on curves versus straightaways, potentially due to centripetal ground reaction force (GRF) production and depends on curve radius. Previous studies found GRF production differences between an athlete's inside versus outside leg relative to the center of the curve. Further, sprinting clockwise (CW) versus counterclockwise (CCW) slows vmax. We determined vmax, step kinematics, and individual leg GRF on a straightaway and curves with 17.2 and 36.5 m radii for nine (8M; 1F) competitive sprinters running CW and CCW and compared vmax to three predictive models. We combined CW and CCW directions and found that vmax slowed by 10.0±2.4% and 4.1±1.6% (p<0.001) for the 17.2 and 36.5 m radius curves versus the straightaway, respectively. vmax values from the predictive models were up to 3.5% faster than the experimental data. Contact length was 0.02 m shorter and stance average resultant GRF was 0.10 BW greater for the 36.5 versus 17.2 m radius curves (p<0.001). Stance average centripetal GRF was 0.10 body weights (BW) greater for the inside versus outside leg (p<0.001) on the 36.5 m radius curve. Stance average vertical GRF was 0.21 BW (p<0.001) and 0.10 BW (p=0.001) lower for the inside versus outside leg for the 17.2 and 36.5 m radius curves, respectively. For a given curve radius, vmax was 1.6% faster in the CCW compared to CW direction (p=0.003). Overall, we found that sprinters change contact length and modulate GRFs produced by their inside and outside legs as curve radius decreases, potentially limiting vmax.

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“…High‐speed running was therefore defined as running at or beyond 60% of maximum speed (muscle activation studies) or 4 m per second (m/s) (kinetic studies) and has been used as the minimum criteria for inclusion in this review. Studies where experimental tasks of high‐speed running focused on acceleration, deceleration, curvilinear, and change of direction running data were excluded, due to the associated deviation in mechanics compared with straight line running 23,24 . Overground running studies were limited to flat surfaces, while treadmill‐based studies were included on two conditions; (1) treadmill gradient was set between 0% and 1% and (2) gravity‐altering treadmills were not used to alter subject's normal mass due to their impact on the outcomes measured 25,26 .…”

Section: Methodsmentioning

confidence: 99%

“…Studies where experimental tasks of high-speed running focused on acceleration, deceleration, curvilinear, and change of direction running data were excluded, due to the associated deviation in mechanics compared with straight line running. 23,24 Overground running studies were limited to flat surfaces, while treadmill-based studies were included on two conditions; (1) treadmill gradient was set between 0% and 1% and (2) gravity-altering treadmills were not used to alter subject's normal mass due to their impact on the outcomes measured. 25,26 If participants' data in a study were recorded only in fatigued states, and/or if exact run speed/relative intensity during data collection was not stated, the study was excluded.…”

Section: Selection Criteriamentioning

confidence: 99%

Quantifying demands on the hamstrings during high‐speed running: A systematic review and meta‐analysis

McNally,

Edwards,

Halaki

et al. 2023

Scandinavian Med Sci Sports

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IntroductionHamstring strain injury (HSI) remains a performance, economic, and player availability burden in sport. High‐speed running (HSR) is cited as a common mechanism for HSI. While evidence exists regarding the high physical demands on the hamstring muscles in HSR, meta‐analytical synthesis of related activation and kinetic variables is lacking.MethodsA systematic search of Medline, Embase, Scopus, CINAHL, SportDiscus, and Cochrane library databases was conducted in accordance with the PRISMA 2020 guidelines. Studies reporting hamstring activation (electromyographic [EMG]) or hamstring muscle/related joint kinetics were included where healthy adult participants ran at or beyond 60% of maximum speed (activation studies) or 4 m per second (m/s) (kinetic studies).ResultsA total of 96 studies met the inclusion criteria. Run intensities were categorized as “slow,” “moderate,” or “fast” in both activation and kinetic based studies with appropriate relative, and raw measures, respectively. Meta‐analysis revealed pooled mean lateral hamstring muscle activation levels of 108.1% (95% CI: 84.4%–131.7%) of maximal voluntary isometric contraction (MVIC) during “fast” running. Meta‐analysis found swing phase peak knee flexion internal moment and power at 2.2 Newton meters/kilogram (Nm/kg) (95% CI: 1.9–2.5) and 40.3 Watts/kilogram (W/kg) (95% CI: 31.4–49.2), respectively. Hip extension peak moment and power was estimated as 4.8 Nm/kg (95% CI: 3.9–5.7) and 33.1 W/kg (95% CI: 17.4–48.9), respectively.ConclusionsAs run intensity/speed increases, so do the activation and kinetic demands on the hamstrings. The presented data will enable clinicians to incorporate more objective measures into the design of injury prevention and return‐to‐play decision‐making strategies.

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Kinematic modifications of the lower limb during the acceleration phase of bend sprinting

Cited by 8 publications

References 24 publications

Are the ground reaction forces altered by the curve and with the increasing sprinting velocity?

Are the ground reaction forces altered by the curve and with the increasing sprinting velocity?

Maximum velocity and leg-specific ground reaction force production change with radius during flat curve sprinting

Quantifying demands on the hamstrings during high‐speed running: A systematic review and meta‐analysis

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